Impulse measuring and recording apparatus



June 17, 1941. T. A. RICH 2,246,003

IMPULSE MEASURING AND nnconnme APPARATUS Filed Nov. 26, 1938 Inventor: Theodor-e Afiich,

ax/M by His Attor-rtz Patented June 17, 1941 IMPULSE MEASURING AND RECORDING APPARATUS Theodore A. Rich, Schenectady, General Electric Company,

New York N. Y., assignor to a corporation of Application November 26,1938, Serial No. 242,543

I 6 Claims. My invention relates to apparatus for measur ing and recording rapidly recurring current impulse phenomenon of varying magnitude andduration. The apparatus of my invention is particularly adapted for measuring and recording the consistency performance obtained during electric welding operations, and the invention will be explained as for such purpose, but it may be used for other purposes.

In connection with electric Welding operations, it is desirable to measure and record the factors influencing each welding operation simultaneously with the welding operation in order that the operator may have acontinuous record to guide him in his work and to' assure that the Welding operations meet the exacting specifications necessary for reliable work. The most important factors are the heating rate of the welding current and its duration, the pressure and area of electrodes, and the conditions of surfaces. The measurement and control of pressure, area and surfaces is readily measured by commonplace means. The device here described measures the ampere-squared-seconds of the welding current.

This application has been divided and divisional applications have been filed as follows: Serial No. 269,805, filed April 24, 1939, claiming the timing control features of the recorder;

Serial No. 269,806, filed April 24, 1939, claiming means for stopping movement of the recording chart when measurement operations cease; Serial No. 307,569, filed December 4, 1939, claiming features for maintaining the recording tape and chart straight as they are advanced; and Serial No. 307,550, filed December 4, 1939, claiming features of the recording apparatus for printi: g spaced calibration marks on the record sheet.

The features of my invention which are believed to be novel and patentable-will be pointed out in the claims appended hereto. For abetter understanding of my invention reference is made in the following description to the accompanying drawing in which Fig. 1 represents a wiring diagram in which my improved measuring and recording apparatus is shown in perspective and is arranged for the purpose of recording the ampere-squared-seconds of spot welding current impulses; Fig. 2 shows details of the chart advancing rolls; and Fig; 3 shows how a marking feature of the recorder may be varied.

In the drawing, l0 represents the power cables leading to the electrodes l2 of spot welding equipment. Thecontrol apparatus which is gen- I erally provided in the power supply to electric welders is not shown. The apparatus which is shown is that embodying the present invention for measuring and recording a quantity proportional to the heat energy consumed in the welding operations at-the electrodes for consecutive welding .operations. These welding operations may be repeated as often as one hundred times or more a minute, and each operation is accompanied by acurrent surge through leads in. The apparatus of my invention responds to these current surges to produce individual records of the ampere-squared-seconds energy of each surge. This requires that the measuring and recording of a given surge must be completed in a time interval of less than one second in duration and the apparatus conditioned to measure and record the next surge. The more important aspects of my invention concern features which enable the electric measuring and recording apparatus to perform their functions accurately in the short time periods mentioned.

In thecircuit of one of the power leads I!) is represented a current transformer ll of a high current reducing ratio. The secondary of the transformer supplies greatly reduced but proportional current impulses to a relay I2 and to the measuring coil l3 of a recording galva- I nometer. The purpose of relay l2 and the vacuum tube and relay circuits shown generally above this relay are primarily to control the timing of the recording operation and. the reconditioning of the galvanometer after each surge measurement. However, before attempting a detail explanation thereof, it will be best to describe the galvanometer recorder.

The galvanometer comprises essentially three parts, first a measuring element energized by coil I3, and having a two-pole stationary magnet l4 and a two-pole magnetic armature l5 secured to the rotary shaft l6; second, a damping element consisting of a disk H of conducting material secured to shaft l6 and one or more stationary permanent magnets [8 which convey a damping flux through the disk I! for damping purposes; and third, a zero return element consisting of a two-pole magnetic vane 19 secured to shaft l6 and a two-pole stationary field magnet 20 which when energized tends to turn its vane 19 into alignment with its pole pieces at approximately the zero position of the shaft l6. A recording arm 2| is secured to shaft 0rd sheet 22 and a printing rod 23.

I8,- -and its outer end extends freely between a recin the form of a roller be- ,nected with the armature neath the printing rod 23. About drum 24 is a belt 25 of carbon paper or its equivalent. The

- record sheet 22 is preferably sufliciently thin as to be transparent so that when the printing rod 23 forces pointer 2| down against the printing platten with the record sheet and carbon paper intervening, a mark is made on theunder surface of the record sheet of the position of pointer 2|, which mark is visible through the transparent sheet. 26 represents a supply roll for the record sheet, and 28 a driving drum for the record sheet. 29 is a small timing motor used for driving the drum 28 for advancing the chart 22. The advance of chart 22 rotates roller 24 and since the carbon paper belt 25 is about roller 24 in contact with chart 22 the carbon paper belt 25 is also advanced by motor 29. The carbon paper belt 25 is advanced over roller 24 at about the same rate as the record sheet is advanced above it, but, except. during the instants of printing, the carbon paper does not transfer marking material to the record sheet.

In order automatically to .stop the advance of the record sheet when welding operations are temporarily discontinued, I have provided a special contact. device for opening the circuit of the timing motor 29. The contacts of this device comprise a metal wheel 3| and a resilient metal brush 32 bearing against the wheel 3| and included in the circuit of motor 29.

As here shown, the metal wheel 3| is urged in a counterclockwise direction by a light spiral spring 33 and has an insulating finger 34 extending from iits periphery which, if rotated clockwise against the upper end of contact 32, forces the "contact away from wheel 3| to open the circuit of the timing motor 29. This contact mechanism is pivotally mounted at 21 and is con- 35 of a relay 38 by rod 30. This relay 36 is energized following the occurrence of a welding surge as will be described subsequently. When the relay 36 is deenergized, the metal wheel 3| is rotated in a clockwise direction since it is on a shaft geared at 280. to the shaft of roller 28 driven by timing motor 29 and in this condition, which is that represented in the drawing, wheel 3| will be driven clockwise so long as the timing motor remains energized through contacts 3l'and 32. V

It is seen that in a short time interval, if the relay 36is not energized, insulating finger 34 will rotate against spring finger 32 and move-it away from wheel 3| to break the timing motor circuit.

This condition of affairs will remain until relay 36 is energized. When this happens the contact assembly is swung to, the right about pivot 21 and the gears at 28c are separated. Now spring 33, which has been wound up, can rotate of the timing motor.

and easier to study than if scattered over an un- 3| counterclockwise until finger 34 is stopped by v contact with a stop 34a. Finger 32 is now in contact with wheel 3| and the timing motor starts in operation to advance the record sheet Ordinarily when surges to be recorded are coming in at a rate of say once per second, the finger 34 does not reach contact 32 but is repeatedly returned against its stop and the timing motor circuit remains energized to advance the record sheet continuously, but as soon as relay 36 re mains deenergized for a somewhat longer period, which period may be made anything desired, the

timing motor circuit is again opened and remains open until the next surge to be recorded occurs. It will be evident that with this arrangement the record sheet will always be advanced so as to leave a clean portion of the record sheet in recording position when the motor stop and hence the first impulse that comes in and starts the timing motor will be properly recorded. This expedient not only saves considerable recording and carbon paper, but it saves wear and tear on the recording apparatus and useless operation Delays incident to renewing the recording paper supply are reduced, and the records which are obtained are condensed necessary length of record sheet.

The printing rod 23 extends over the recording swing of pointer 2| and may be resiliently suspended and provided with a magnet 38 which will be momentarily energized at the proper time, as hereinafter explained, to perform a recording operation.

The deflecting, damping and zero return torques of the recorder are large in comparison with the moment of' inertia of the moving parts; mounted on shaft Hi.

In the iron vane type of measuring instrument here used the deflecting torque is proportional to the square of the current (I) flowing in its coil I3. The damping torque is proportional to the angular velocity (w) which is equal to a damping constant K times 1 The angular travel of the pointer from a zero position, when there is no zero restoring torque and neglecting friction and moment of inertia, is equal to the average angular velocity KI multiplied by the time duration (t) of the surge. The moment of inertia of themoving parts of the instrument is made small in comparison with the torques referred to and therefore does not materially alter the deflection characteristics of the instrument, but to the extent thatit does it may be compensated for according to the following explanation. That small portion of the up scale torque of the instrument during acceleration of the pointer up scale, which is used up in overcoming the inertia of the moving parts is substantially equivalent to the kinetic energy remaining in the moving parts when the up scale torque ceases. This will cause the pointer to continue to be moved up scale until this energy is used up by the opposing damping torque. If then at the end of a surge we allow pointer 2| to move up scale until it stops before we print the record, the recording position of the pointer will be proportional to Ft within anegligible degree of error. If the surge is of relatively low current value the acceleration and deceleration forces of the moving parts will both be correspondingly small. If the surge is of a relatively high current value the acceleration and deceleration forceswill both be correspondingly large so that as long as we allow the pointer to come to 'restbefore the record is printed the recording position will be proportional to Ft. The

fiections and reduces to approximately a zero.

value at the zero position of the shaft.

I provide a timing system responsive to the operation of relay [2' for delaying the printing of the position of the recording arm 2| for a suitable period after the end of each surge and also for controlling the time sequence of operations necessary to print the record and restore the printing arm to a zero position in readiness for the next surge.

The timing system and the relays controlled thereby are supplied by a constant voltage source 40 which, for the condenser and resistance values hereinafter mentioned by way of example, may be a 220 volt, 60 cycle, A. C. source.

Connected across source 40 is a relay winding 4|, a vacuum tube .42, and a 2 microfarad supply condenser 43 in series relation. When current flows through this circuit, relay 4| is energized and condenser 43, if not by-passed, is charged.

Surge responsive relay l2 operates a threepole double throw switch 44, the primary purpose of which is to connect a 0.1 microfarad transfer condenser 45 and a 0.3 microfarad transfer condenser 46 across condenser 43 to transfer a portion of the charge on supply condenser 43 to the smaller condensers 45 and 46 when a surge starts and to connect condenser 45 across the filament and control grid of vacuum tube 42 and condensery46 across the filament and control grid of a vacuum tube 41 when the surge has ended.

In the energized position of relay l2 the conwhich is connected directly across source through the coil of. relay 48 will be passing current and relay 48 will be energized. Condenser 43 will be charged and condensers and 46 discharged and the relay connections will be as represented in Fig. 1. No surge current will be flowing in the instrument coil l3 or in the coil of relay l2, and the galvanometer pointer will stand in a zero position with a stop 51 of its moving system resting against a zero stop 58.

To assist in explaining the operation of the apparatus there follows an approximate time table of events during a surge cycle. Thefirst column of the table gives the timing of the events starting with the steady state condition. The several other columns indicate the condition of the different elements identified at the head of each columnat the different times indicated. The first horizontal line of the table below the identifying headings gives the steady state or idle condition mentioned above, and this is the condition of the apparatus as shown in Fig. 1.

Relay currents Condenser voltages Coil currents Time 12' 41 48 36 38 43 45 46 13 20 Milli- Milli- Milli- Amperes amperes amperea Amperes amperes Steady state. 0 0 20 0 0 300 0 0 0 0 Surge starts. 5 Neg. 20 0 0 240 240 240 5 0 Surge stops 0 0 0 0 0 0 240 240 0 0 .1 see. later 0 2O 0 Energized Energized 0 30 or less 150 0 0 .11 see. after surge stops. 0 20 0 Energized 0 0 0 125 0 30 v .4 sec. after surge stops. 0 20 20 Energized 0 10 0 30 or less 0 3O .5 see. after surge stops. 0 0 20 0 0 300 0 0 0 O nections of this switch, as first mentioned above, are made through the upper stationary contacts of the switch 44, and when relay i2 is deenergized, which is the condition shown, the second mentioned connections are made through the lower sets of stationary contacts of switch 441.

Vacuum tube 41 is connected across source 44 in series with a relay winding 48 having contacts arranged to by-pass and discharge condenser 43 through a 100 ohm resistance 49 when relay 4% is deenergized..

It will also be noted that when switch 44 is in the deenergiz'ed position shown and condensers 45 and 46 are connected to bias thetubes 42 and 4'! respectively, the biasing charges of these condensers leak oiT through megohm resistances 50 and 511 respectively, which resistances are at this time connected across condensers 45 and 45 respectively.

Stabilizing resistances of about megohm each are connected in the grid leads of tubes 42 and M7.

Relay 4! when energized energizes relay 36 through wire 52, and. printing relay 38 through Contact 53 of relay 36 and wire 54. Relay 36 in In the steady state condition relay 48 is energized by about 20 milliamperes. All of the other relays and coils indicated are deenergized. Conaddition to performing the function previously described in connection with the control of the timing motor 29 serves when energized to open the circuit of printing relay 38 and to close the circuit of the zero return magnet 20 of the recording meter, through a contact 55 and Wire 56. In the idle or steady state condition of the timing system, relays l2, 4|, 36, 38 and zero return magnet 20 'will be deenergized. Tube 41 denser 43 has a charge of about 300 volts since it tends to charge up to the peak voltage of. the 220 volt A. C. source 40. When a surge starts the conditions indicated in the next line of the table exist. Relay 5? is energized and operates switch 44 to the raised position and the charge on condenser 43 is distributed between all three condensers to give voltages of about 240. There may be some slight flow of current through tube 42 because of this lowering in voltage but not enough to operate relay 4i, and its current is indicated as being negligible.

The surge current flows through galvanometer.

secondary, but it will be understood that this current may vary in accordance with the primary surge current value. The galvanometer of course now starts to move the recording pointer up scale until the surge stops and we arrive at the condition shown in line three of the table. The length of the surge may vary. A common length of a spot welding current surge is six cycles of a 60 cycle frequency. When the impulse stops (line three of the table) relay I2 and coil I3 are deenergized. Switch 44 drops to the lower contacts. The 240 volt charge on condenser 46 is impressed across-filament and grid of tube 4'! in a direction to stop current flow therethrough and relay 48 is deenergized, and this short-cirvolts or less and tube deenergized zero return returning pointer 2| towards a zero position with in line six of the table will exist.

the current through tube 42 cycle may be changed cuits condenser 43 through resistance 49 and the voltage of condenser 43 drops rapidly toward the zero value indicated. The 240 volt charge on condenser 45 is impressed between filament and grid of tube 42 and is in a direction to hold this tube at out off.

The damping element of the galvanometer is now bringing the up scale movement of the pointer to a stop. About one tenth second later the conditions in line four of the table will exist. The charge on condenser 45 has leaked off through resistance 5|luntil its charge is 30 42 is no longer held at out off and passes about 20 milliamperes current through resistance 49, the closed contacts of deenergized relay 48 and the coil of relay 4|. Relay 4| is energized and has closed its contacts and has energized normally deenergized print relay 36 which prints the position-of the now stationary pointer 2| at the top of its swing. Relay 36 which is slow acting as compared to the print relay is energized and has just started pulling in its armature. The conditions rapidly change to those indicated in linefive of the table at about .11 second after the surge has stopped. Here relay 36 has completed its pull in operation and deenergized print relay 38 and momentarily energized the coil of the normally device 20, which starts a torque proportional to the pointer deflection from zero. The charge on condenser 46 has been leaking off through resistance 5| but tube 41 is still held at out ofi.

.4 second after the surge stops the conditions The pointer has been returned to zero position. against stop 58, with the return coil still energized but now in a rotary position where its returning torque is very small and nearly of a zero value. This, together with the checking action of the magnetic damping element, has quickly brought the pointer to a zero position yet without shock and without tendency to bounce away from the stop. The charge on condenser 46 has leaked away until tube 41 passes current, relay 48 is energized and and relay 4|, in-

stead of being by-passed through the contacts of relay 48, starts to charge condenser 43 and has dropped somewhat below 20 ma. but is still sulficient to maintain relay 4| in its energized position. One-half second after the surge has stopped, the conditions in line seven of the table will exist. At this time condenser 43 has become substantially charged, the flow of current through tube 42 and relay 4| has stopped or dropped to a negligible value, and the contacts of relay 4| are open, relay 36 is deenergized and returned to open position, thereby deenergizing the zero return device 20. This returns the apparatus to the steady state condition upon com-. pleting the cycle of events and the apparatus is in readiness to record the next surge.

It is seen that this cycle is completed in onehalf second after the surge stops. Assuming the average length of surge is one-tenth second in duration, a normal surge may occur and be recorded and the apparatus conditioned for recording the next surge in 0.6 second. Thus surges of the character contemplated may occur at the rate of 100 per minute and be measured and recorded by this apparatus adjusted as above described. ,It will be understood that the timing by changing the times required for condensers 45 and 46 to discharge and remove the cut ofi bias on tubes 42 and 41. For example, to decrease the time delay caused by condenser 46 andtube 41 I may either reduce the value of condenser 46 or give it a higher discharge rate by decreasing resistance 5|. Also the time delay intervals of both tubes 42 and 41 may be reduced by reducing the capacity of condenser 43. This will result in a lower initial charge on condensers 45 and 46 and hence give them a shorter discharge interval. These and other adjustments may be made to vary the timing sequence and while certain circuit constants and timing conditions have been-given by way of example, the invention is not limited to the particular time cycle of adjustment described.

Solong as surges come in frequently, the timing motor 29 will remain in operation, but if the surges cease occurring frequently the time delay means consisting of finger 34 of contact wheel 3| will, after a short time delay, rotate into contact with resilient contact 32 to open the timing motor circuit and stop the advance of the recording paper.

The welding circuit is usually controlled by a vacuum tube apparatus (not shown) such that a welding surge lasts for a definite number of cycles. If anything happens to such control apparatus to shorten or lengthen the surge, or if such control apparatus becomes defective to vary the voltage across the electrodes or to skip a portion of the normal surge, while conditions at the welding electrodes remain normal the increase or decrease in the I 1. product measured and recorded by my surge recorder will immediately show up by the records produced. Likewise, if the power control apparatus functions properly but the resistance between the weld electrodes incident to a welding operation varies from normal due to failure of proper contact pressure, improper spacing of electrodes or defective material being welded so as to change the factor, I in the product measured by the recorder apparatus, such defective condition will be immediately revealed by the variation from normal of the records obtained. supply voltage varies to afiect I it will be revealed in the record.

The nature of the records obtained are shown by the dots indicated at 66 on record sheet 22. As illustrated, the printing rod 23-is provided with a removable or adjustable section 6| of insulating material such as rubber. At the lateral boundaries of this insulated section there are provided raised printing ridges 62, which, when the printing relay 38 is energized, print boundary lines 63 on the record sheet-22 when the records 66 are printed.

The front section 64 of the printing rod which holds rubber part BI and the boundary printing ridges 62 is either removable or adjustable. In

the example shown, the adjustable part 64 is fastened to the main part 23 of the printing rod by screws 65. When these screws are removed, part 64 with insulating part 6| and the boundary printing ridges may be moved laterally or removed entirely and replaced by another section 64' Similarly if the line (see Fig. 3) having the insulated part 6| wider or narrower than the part 6| of Fig.

upper and lower limits of satisfactory welding surges and so long as the records fall between these lines, as shown for example by the records 60 in Fig. 1, the welder is assured that the welding surges contain the proper amount of heat energy to give satisfactory welds.

If the records 60 go lower as at point 60a or higher as at point 602) than the limits set, it may be assumed that something is wrong with the power control apparatus or the welding apparatus, and the trouble should be located and corrected before further welding operations are made.

If pointer 2! is outside the boundary limits 62 when a record is made such as at 60a or 6%, the pointer is opposite a conducting portion of the printing rod and an electric contact is made between the metal pointer and metal rod at the instant of printing. This contact arrangement is included in a circuit which may include one or more of the following: a visual signal 66, an audible signal 61, a control relay 68, as well as a source of supply 69.. The relay 68 may be arranged to shut off the power supply to the welder so that no further use thereof may proceed until the apparatus has been checked and the con-- dition corrected. When the pointer is opposite the insulated part 6| when the record is printed the lower edge of the insulated part strikes the pointer and hence the signal or control circuit is not energized for satisfactory welding surges. The connection of the signalling circuit to the recording pointer shaft should be through a conlength of the belt at its opposite ends.

nection such as a weak spiral. which has negligible turning effect on the shaft in any position In order to avoid trouble with the carbon paper belt 25 and-record paper 22, I have found that certain precautions are very desirable. It is difiicult to providea carbon paper or cloth belt 25 of exactly the same length at both ends. For example, the belt may be formed by a sheet of carbon paper of the desired width and length which, whenthe ends are pasted together, form a belt. In pasting the ends of the sheet together to form a belt, one peripheral side of the belt may be found to be 1 3' inch longer than the other in spite of care being'taken to prevent any such discrepency. Such a belt when simply placed on parallel rollers such as the rollers 24 and ill and driven as here contemplated, will not run true but will invariably work endwise towards that end of the belt which is the longest. Even collars such as collars H shown at the ends of roller 24 will not prevent an uneven belt of carbon paper from working endwise and climbing out over such collar. This troublesome difficulty has been overcome by the use of a wrinkle bar 12 having bends l3 beneath the paper belt near the ends of such belt where it is fed onto roller 24. These bends crowd the end edges of the paper belt inward and cause it to wrinkle up slightly just as it passes into platten roller 2d and the belt is made sufficiently loose to permit this without tearing. When the belt passes over roller 24, the chart paper 22 is outside and under suflicient tension to drive the carbon paper belt and to fiatten out the wrinkles in and without causing creasing of the carbon paper. This pressing and driving action of chart 22 on the carbon paper over a. limited periphery of roller 24' allows the belt to adjust itself, the wrinkles in the long end of the belt apparently being pressed out in a forward direction and the wrinkles in the short end of the belt apparently being pressed out in a reta'rding direction to the extent necessary to althe same.

The chart 22 used is a relatively thin lightweight paper in order that it will be suiliciently transparent to enable the records, which are made on the under side of the chart, to be clearly visible therethrough. It is impracticable to drive such a chart with a toothed drum having driving teeth projecting through holes punched along the edges of the chart. The chart driving arrangement used, and which has been referred to generally above as a driving drum 28, requires some further explanation. The driving drum 28 maybe constructed as indicated in Fig. 2 having a soft rubber cylindrical driving section 14 at its center and soft rubber inwardly tapered guiding sections 15 at its two ends. The remainder of this drum is made of reduced diameter and may be made up of metal parts which serve as supporting and spacing parts, but do not enter into driving contact with the paper. Beneath driving drum 28 is another drum made up of a long central part 16 and short end parts ll. These three parts are so supported as to be freely rotatable independently of each other. Part 16 is pressed in driving contact with part M of drum 28 and the chart is gripped between these two parts and they constitute the main driving elements of the arrangement. End roller parts Tl are slightly smaller in diameter than part l6 and they are in driving contact with the outer cylindrical portions of guide roller parts 15, The maximum diameter of parts 15 is slightly greater than the diameter of cylindrical part H, but the minimum diameters of these parts are The chart is of a width equal to the distance between the inner ends of parts 15 and is normally driven in a central position with its end edges in line with the inner ends of the parts 15. In case the chart tends to creep towards one side or the other of such central position, one edge rides up on the cone-shaped surface of part and there is an immediate tendency for such edge to be driven faster than the middle of the chart due to the increased diameter of part l5 and the fact that parts 14 and 75 are driven at the same speed. This straightens the chart and returns it to a central driving position. This correcting effect of the cone-shaped roller parts 75 at any instant is in proportion to extent of chart displacement from a central position at the driving drum. Guide collars H maintain the chart properly centered under the recording position and hence such correcting effects as occur at the driving drum do not displace the record on the chart.

What I claim as new and desire to secure by Letters Patent of the United States is:

1. In a surge current recording instrument, a rotary recording element having a zero position, an electro-magnet connected to be energized in response to the surge current for rotating said zero value in brought to rest by the damping means, the torque effects of the electro-magnet and damping means on said rotary recording element being large in comparison with themoment of inertia of said recording element, said apparatus producing a record which is a measure of the product of the square of the surge current and its duration.

2. In a recording instrument for recording current impulses of short duration at frequentintervals, a shaft having a zero position, a current responsive electro-magnet for rotating said shaft in an up-scale direction in response to the current impulses to be recorded, a normallydeenergized zero return electro-magnet for rotating said shaft in a down-scale direction in response to constant current impulses, magnetic damping means for said shaft effective in both directions of rotation, a stop for said shaft for preventing its rotation in a down-scale direction beyond the zero position, said zero return electro-magnet producing a zero return torque which is proportional to the up-scale position of the shaft, which torque diminishes to approximately means for recording the up-scale deflection of said shaft, and means for momentarily energizing the zero return magnet immediately following such recording to return said shaft to a zero position.

3. In a recording in trument for recording the zero position of said shaft,v

- ing the occurrence of a surge, a normally deenergized zero return electro-magnet for rotating said recording element in down-scale direction to a. zero position, normally deenergized electhe up-scale position of current surges of short duration at frequent intervals, a shaft having a zero position, a current-responsive electro-magnet for rotating said shaft in an up-scale direction in response to current surges to be recorded, a normally deenergized Zero return electro-magnet for rotating said shaft in a down-scalei direction to a zero position in response to constant current impulses, damping means for damping the rotation of said shaft in both directions of rotation, a record sheet, a recording stylus operated by said shaft for recording on said record sheet but normally disengaged therefrom, a normally deenergized printing electro-magnet for establishing engagement of the recording stylus and record sheet, and timing means responsive to the occurrence of a surge to be recorded for momentarily energizing the printing electro-magnet and the zero return electro-magnet in succession at predetermined short intervals of time following the discontinuance of such surge.

4. Apparatus for recording surge currents of short duration and frequent occurrence comprising a rotary recording element having a zero position, an electro-magnet responsive to the surge current to be recorded for rotating said recording element in an up-scale direction dur- .manent magnet damping trically operated means for-producing a record of thev up-scale position of the recording, element, means for damping .the rotary movement of said recording means in both directions of rotation, switches foropening and closing energizing circuits for the record producing electrically operated means and the zero return electro-magnet, and timing means, the timing operation of which is started in response to and at the time of the interruption of a surge, for first closing and opening of the record-producing electrically operated means, and second, closing and opening the energizing switch for the zero return magnet, said timing means delaying the first mentioned switching operation until the recording element has been brought to rest in an up-scale position by said damping means.

5. Surge recording apparatus comprising a measuring instrument having a movable recording member, a surge responsive magnet for moving said recording member up-sc-ale from a zero position, a recording magnet for recording said member, a zero return magnet for returning said recording member to a zero position, normally open supply circuits for the recording and zero return mag- ,nets including a time delay switch and a transfer switch in series, the transfer switch closing branch circuits to the recording and zero return magnets alternately in response to the closing of the time delay switch, and timing means responsive to the occurrence of a surge for conditioning said time delay switch for operation a predetermined time after the surge ceases.

6. A recording instrument capable of recording current surges which may occur as rapidly as per minute comprising an electrical measuring instrument having a moving element actuated in response to current surges by forces proportional .to the square of the surge current, permeans resisting the movement of said element, the moment of inertia of said moving element being sufhciently small as compared to the actuating and damping forces that the extent of its movement per surge is substantially proportional to the square of the surge current times its. duration, means for recording said movements and means for returning said moving element to a zero position following each surge.

THEODORE A. RICH.

the energizing switch I 

